|
HS Code |
841162 |
| Chemical Name | Dibutyryl Cyclic Adenosine Monophosphate Sodium |
| Synonyms | db-cAMP sodium salt, N6,2'-O-dibutyryl cyclic AMP sodium salt |
| Molecular Formula | C18H24N5NaO8P |
| Molecular Weight | 507.37 g/mol |
| Cas Number | 3968-87-2 |
| Appearance | White to off-white powder |
| Solubility | Soluble in water |
| Storage Conditions | Store at -20°C, protected from light and moisture |
| Purity | ≥98% (HPLC) |
| Usage | Cell permeable cAMP analog for research use; used to activate protein kinase A signaling |
As an accredited Dibutyryl Cyclic Adenosine Monophosphate Sodium factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass vial containing 100 mg Dibutyryl Cyclic Adenosine Monophosphate Sodium, labeled with product name, CAS number, and storage instructions. |
| Shipping | Dibutyryl Cyclic Adenosine Monophosphate Sodium is shipped in tightly sealed containers under dry, cool conditions. It is typically packed with desiccants to prevent moisture exposure and may require cold packs or temperature control during transit to maintain stability. Handle and transport following appropriate chemical safety regulations and guidelines. |
| Storage | Dibutyryl Cyclic Adenosine Monophosphate Sodium should be stored in a tightly sealed container, protected from light and moisture. Keep at -20°C for long-term storage. Avoid repeated freeze-thaw cycles. Store in a dry, well-ventilated area away from incompatible substances. Proper storage helps maintain stability and prevents degradation of the compound. Always follow safety guidelines and wear appropriate protective equipment when handling. |
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Factories work with a range of cyclic nucleotide derivatives, but dibutyryl cyclic adenosine monophosphate sodium (dibutyryl cAMP sodium) stands out in laboratories for its cell membrane permeability and stability. This molecule, bearing the model DB-cAMP.Na, takes the structural foundation of cAMP and modifies it with butyryl esters, leading to a compound that bypasses the challenges traditional cyclic AMP faces. Researchers come to us looking for consistency, purity, and transparency. They ask about differences, about supply, about what they can trust beneath the lid of every container.
Scientists appreciate that dibutyryl cAMP sodium enters cells more efficiently than standard cAMP, thanks to its increased lipid solubility. We see that difference regularly when talking to academic teams or pharmaceutical clients—it’s clear the interest isn’t theoretical. In practice, dibutyryl cAMP sodium supports work in cell signaling, neuronal growth, cardiac research, and studies involving differentiation or proliferation. Many experiments depend on cAMP analogues, yet only a few can deliver time-dependent, consistent results without frustrating batch issues or solubility headaches. From our own production floor to the centrifuges in university labs, that’s what keeps this derivative near the top of client requests.
Our production relies on a controlled process with direct monitoring of each chemical step, avoiding shortcuts that risk contamination. We find that careful solvent selection and drying protocols, measured by HPLC and NMR, keep DB-cAMP.Na above the 98% purity mark. Consistency in the sodium salt form is just as crucial. Researchers often report sensitivity in biological assays and cell cultures, so the presence of free acid or other salts can derail entire project lines. Efforts to reduce endotoxin and residual solvent content occupy a major part of our QA workflow—nobody wants to risk altered experimental signaling because of a dirty batch.
Dibutyryl cAMP sodium typically comes as a white to off-white powder, occasionally appearing slightly granular. This is not a sign of lower quality, but more often a result of recrystallization environments or drying rates. Over the years, customers have become wary of variations; we address these concerns by documenting our process and validating each packaging run. Measured batches range from the gram scale for academic labs to multi-kilogram drums for established production environments. Our team verifies both moisture content and the sodium salt percentage to guarantee stable freezing, reconstitution, and long-term storage. Often, customers mention previous frustrations with caking or clumping from other suppliers—diligent factory-level controls make the difference.
Most buyers use dibutyryl cAMP sodium in life sciences. Researchers looking at smooth muscle relaxation, kinase activation, adipocyte differentiation, or neural regeneration assign the compound to pathways that regular cAMP struggles to activate. They want rapid uptake, minimal breakdown by phosphodiesterases, and predictable cellular dynamics. In tissue culture, we’ve witnessed investigators push their protocols to higher-throughput settings, enabled largely by the way dibutyryl cAMP sodium delivers consistent cyclic nucleotide action. For industrial teams in preclinical or drug discovery, the focus shifts slightly. High-volume clients demand full traceability and batch-to-batch reproducibility, with clear cost management from the production run through shipping. Our logistical flexibility stems from practical experience shipping sensitive biochemicals locally and abroad.
We hear about new application areas on a regular basis. Stem cell engineers modify neuronal lines, developmental biologists map receptor responses, and pharmaceutical firms develop small-molecule screens—all relying on dibutyryl cAMP sodium to activate protein kinases or modulate gene expression. In toxicology, the product permits controlled cAMP stimulation in primary cell cultures. Its defined action window allows scientists to study precise cell fate events without waiting through unnecessary delays tied to membrane-impermeable analogues. In contract manufacturing, teams sometimes use it for diagnostic kit development, capitalizing on its consistent read-out properties. Consistency and clarity support reproducibility—a principle our production team takes heavily into account.
Traditional cAMP analogues present unique challenges for cellular uptake, solubility, and degradation rates. Many times, we get questions about how dibutyryl cAMP sodium squares up against 8-Br-cAMP, 8-pCPT-cAMP, or regular cAMP salts. The difference comes down to balance: dibutyryl cAMP sodium, with its dual butyryl substitution, is less susceptible to phosphodiesterase breakdown, yet retains good solubility in aqueous buffers when paired as the sodium salt. This offers a crucial advantage when tight control of intra- and extra-cellular levels matters. Other analogues, such as the 8-substituted derivatives, show greater resistance to breakdown but sometimes lack broad cellular permeability or can introduce unwanted side-signaling. We field these technical questions every month, guiding clients toward the right product for their experimental design and, when appropriate, walking through the rationale behind choosing dibutyryl cAMP sodium for intracellular signaling studies. Many industrial users come back after comparing the effectiveness of multiple analogues; in feedback sessions, they report that the butyryl derivatization often sets a more predictable experimental pace, especially in multi-day protocols.
The rise in demand for high-quality cyclic nucleotide derivatives puts pressure on every link in the production chain. Shortages of key starting materials, changes in regulatory requirements, and rising transportation costs can ripple through pricing and availability. From the manufacturing perspective, these aren’t abstract supply issues—they require day-to-day risk management. We audit each raw material lot, adjusting our procurement to ensure long-term continuity, even as demand fluctuates. In response to feedback, we added additional in-process controls: intermediate purity checkpoints, stepped ion-exchange rinses, and more frequent final testing. This slows down the process on our end but directly prevents the kinds of inconsistent performance customers describe. While some competitors pivot to faster, higher-output synthesis at the expense of purity, we opt for stricter validation steps, ensuring users know exactly what enters their workflows.
Every few months, debate arises over international shipping protocols and local regulatory requirements. Dibutyryl cAMP sodium, though not classified as a hazardous substance in most jurisdictions, sits in a gray area when it comes to import controls for biochemical research products. We routinely update shipping documentation, including data on shelf life, moisture controls, and trace impurities. If customs agencies require more detailed composition analysis or batch certificates, we respond swiftly, drawing on full in-house documentation and years of compliance experience. Clients appreciate proactive communication here. Doing so avoids project interruptions, helps forecast realistic delivery times, and builds a real manufacturer-customer partnership hard to replicate through third parties.
While most investigators request standard dibutyryl cAMP sodium, a smaller number partner with us to discuss custom salt forms, particle-size modifications, or sterile packaging. For niche applications in regenerative medicine or clinical trials, we sometimes design lots with extra-low endotoxin or pyrogen levels. In these cases, direct discussion with the end-user uncovers subtle differences in protocol or storage requirements. Scale-up requires more than copying lab-scale steps; it includes dedicated batch documentation and sometimes enhanced microbiological analysis. If a client raises concerns about packaging stability over long-haul shipping, our packaging engineers review raw material compatibilities and run humidity-exposure tests, strengthening our feedback loop between chemistry, logistics, and the customer’s hands-on reality.
Some early-stage startups in the biopharma space look for GMP-level documentation, not just research-grade analysis. We’ve met this by drawing clear boundaries around non-GMP versus GMP-ready batches. CoA packages, batch history, and analytical data all tie back to our internal lot tracking, giving even small-lot buyers the confidence that their results will hold up in audits and regulatory reviews. The investment in time and equipment pays off as our factory’s reputation spreads through word of mouth—a crucial reality in a field where trust moves faster than marketing.
Having shipped DB-cAMP.Na across four continents, we've tracked shelf life, humidity tolerance, and freeze-thaw resilience from first-hand reports and ongoing QC analysis. At room temperature, short-term exposure doesn't threaten compound purity, but we recommend storing at -20°C for any lot intended for use beyond six months. Repeated freeze-thaw cycles should be minimized, as they can promote hydrolysis or clumping that affects dissolving time—something every technician notices right away in the lab. Customers sometimes ask about lyophilization after reconstitution: while it’s possible, our standard product form avoids common pitfalls by managing residual moisture before sealing. By working directly with recipients on storage and handling protocols, we resolve most routine challenges before a batch ever leaves our facility.
Direct feedback from researchers and industrial users helps us refine not just purity standards, but packaging design, documentation, and ongoing support. We keep a tight circle between our manufacturing chemists, customer service, and end-users. A query about precipitation in buffer prompts us to adjust test parameters for that series. Requests for extra documentation, like shipping temperature logs or expanded impurity profiles, become routine offerings for larger orders. Failures in the field, though rare, trigger root-cause reviews and corrective action—because researchers and manufacturers both stake reputations on reliable results.
Some customers moved to us after dealing with fragmented supply chains or hidden resellers who lacked real manufacturing oversight. The difference shows most clearly in crisis moments—a delivery delay, a customs mix-up, or an unexpected reagent question. Real manufacturers work through these issues arm-in-arm with customers, providing new documentation or overnight samples. Experience teaches us that everyone in the scientific ecosystem, from bench scientist to bulk buyer, depends on transparent, accountable suppliers willing to answer every question with specifics, not marketing platitudes.
Dibutyryl cAMP sodium’s importance doesn’t fall along regional lines; whether destined for university spinouts in Europe, biopharma pilot plants in the U.S., or research units in Asia, the same core questions arise. What is the limit of batch-to-batch impurity? How does this sodium salt tolerate shipping at 30°C? Will the compound perform reliably in precisely modified in vitro conditions? Our experience managing diverse shipping climates, customs protocols, and storage facilities means we build direct relationships with logistics partners, updating our procedures with every completed order and learning from clients who face local storage issues or import rules. The best product is the one that supports its users, wherever they work—a truth we see played out in hundreds of customer conversations each year.
Years on the shop floor steeped us in the realities behind every gram of dibutyryl cAMP sodium. Each production run, batch test, and feedback survey shapes how we deliver a product that serves, rather than frustrates, the diverse community pushing biological research forward. Our choices aren’t theoretical—they affect drug discovery, cell signaling breakthroughs, assay reproducibility, and the day-to-day pace of scientific progress. By investing in tight process control, open feedback channels, and a commitment to substance over flash, we keep building on past experience, serving not just the next customer, but the future of research itself.
